Effects of household-scale cooking on volatile compounds, sensory profile, and hypotensive effect of Kenikir (<i>Cosmos caudatus</i>)

Dody Dwi Handoko; Anisa Maharani Kaseh; Laras Cempaka; Wahyudi David; Bram Kusbiantoro; Afifah Zahra Agista; Yusuke Ohsaki; Hitoshi Shirakawa; Ardiansyah; Dody Dwi Handoko; Anisa Maharani Kaseh; Laras Cempaka; Wahyudi David; Bram Kusbiantoro; Afifah Zahra Agista; Yusuke Ohsaki; Hitoshi Shirakawa; Ardiansyah

doi:10.3934/agrfood.2023011

AIMS Agriculture and Food

2023, Volume 8, Issue 1: 198-213. doi: 10.3934/agrfood.2023011

Previous Article Next Article

Research article

Effects of household-scale cooking on volatile compounds, sensory profile, and hypotensive effect of Kenikir (Cosmos caudatus)

1.
Laboratory of Flavor Analysis, Indonesian Center for Rice Research, Ministry of Agriculture, Subang 41256, Jawa Barat, Indonesia
2.
Department of Food Technology, Universitas Bakrie, Kawasan Epicentrum, Jalan HR Rasuna Said Kav. C. 22, Jakarta 12920, Indonesia
3.
Agroindustry Research Center, National Research and Innovation Agency, Tangerang Selatan 15314, Banten, Indonesia
4.
Laboratory of Nutrition, Graduate School of Agricultural Science, Tohoku University, Sendai 980-8572, Japan

Received: 19 September 2022 Revised: 04 January 2023 Accepted: 02 February 2023 Published: 14 February 2023

Kenikir (Cosmos caudatus) can be used in the preparation of raw and cooked vegetables in some Indonesian dishes. The cooking process may affect the appearance, chemical properties, and flavor of kenikir. This study aims to determine the effect of household scale cooking on the volatile compounds, sensory profiles, and hypotensive activity of kenikir. Fresh kenikir samples and samples boiled or steamed at 100 ℃ (for 3 and 5 minutes) were analyzed for volatile compounds compositions (solid-phase microextraction-Gas chromatography-mass spectrometry, SPME-GCMS), sensory profiles by free choice profiling, and in-vivo study by using stroke-prone spontaneously hypertensive rats (SHRSP)—a model of spontaneous hypertension. The GCMS analysis identified 30 volatile compounds from 5 compound groups, namely alcohols (2 compounds), benzenes (3 compounds), esters (3 compounds), monoterpenes (10 compounds), and sesquiterpenes (12 compounds). Several compounds, namely (Z)-3-hexenol, α-cadinol, and 3-carene were only detected in fresh kenikir, whereas β-myrcene and β-elemene compounds were only identified after cooking. The principal component analysis of sensory attributes associated fresh kenikir with bright color and minty taste, steamed kenikir with floral aroma, and boiled kenikir with juicy, moist, tender, and smooth texture. Furthermore, a hypotensive effect was shown in the water extract of kenikir after 2 and 4 hours of single oral administration in SHRSP. In summary, the heating process (boiled and steamed) of kenikir has changed its volatile compound composition, which can affect its sensory profiles. In addition, the water extract of kenikir can diminish hypertension in SHRSP.

Keywords:

Citation: Dody Dwi Handoko, Anisa Maharani Kaseh, Laras Cempaka, Wahyudi David, Bram Kusbiantoro, Afifah Zahra Agista, Yusuke Ohsaki, Hitoshi Shirakawa, Ardiansyah. Effects of household-scale cooking on volatile compounds, sensory profile, and hypotensive effect of Kenikir (Cosmos caudatus)[J]. AIMS Agriculture and Food, 2023, 8(1): 198-213. doi: 10.3934/agrfood.2023011

Related Papers:

[1]	Hongyan Xu . Digital media zero watermark copyright protection algorithm based on embedded intelligent edge computing detection. Mathematical Biosciences and Engineering, 2021, 18(5): 6771-6789. doi: 10.3934/mbe.2021336
[2]	Haoyu Lu, Daofu Gong, Fenlin Liu, Hui Liu, Jinghua Qu . A batch copyright scheme for digital image based on deep neural network. Mathematical Biosciences and Engineering, 2019, 16(5): 6121-6133. doi: 10.3934/mbe.2019306
[3]	Shanqing Zhang, Xiaoyun Guo, Xianghua Xu, Li Li, Chin-Chen Chang . A video watermark algorithm based on tensor decomposition. Mathematical Biosciences and Engineering, 2019, 16(5): 3435-3449. doi: 10.3934/mbe.2019172
[4]	Wenfa Qi, Wei Guo, Tong Zhang, Yuxin Liu, Zongming Guo, Xifeng Fang . Robust authentication for paper-based text documents based on text watermarking technology. Mathematical Biosciences and Engineering, 2019, 16(4): 2233-2249. doi: 10.3934/mbe.2019110
[5]	Chuanda Cai, Changgen Peng, Jin Niu, Weijie Tan, Hanlin Tang . Low distortion reversible database watermarking based on hybrid intelligent algorithm. Mathematical Biosciences and Engineering, 2023, 20(12): 21315-21336. doi: 10.3934/mbe.2023943
[6]	Xuehu Yan, Xuan Zhou, Yuliang Lu, Jingju Liu, Guozheng Yang . Image inpainting-based behavior image secret sharing. Mathematical Biosciences and Engineering, 2020, 17(4): 2950-2966. doi: 10.3934/mbe.2020166
[7]	Shaozhang Xiao, Xingyuan Zuo, Zhengwei Zhang, Fenfen Li . Large-capacity reversible image watermarking based on improved DE. Mathematical Biosciences and Engineering, 2022, 19(2): 1108-1127. doi: 10.3934/mbe.2022051
[8]	Qiuling Wu, Dandan Huang, Jiangchun Wei, Wenhui Chen . Adaptive and blind audio watermarking algorithm based on dither modulation and butterfly optimization algorithm. Mathematical Biosciences and Engineering, 2023, 20(6): 11482-11501. doi: 10.3934/mbe.2023509
[9]	Zhenjun Tang, Yongzheng Yu, Hanyun Zhang, Mengzhu Yu, Chunqiang Yu, Xianquan Zhang . Robust image hashing via visual attention model and ring partition. Mathematical Biosciences and Engineering, 2019, 16(5): 6103-6120. doi: 10.3934/mbe.2019305
[10]	Shuyan Liu, Peilin Li, Yuanhao Tan, Geqi Ding, Bo Peng . A robust local pulse wave imaging method based on digital image processing techniques. Mathematical Biosciences and Engineering, 2023, 20(4): 6721-6734. doi: 10.3934/mbe.2023289

Abstract

1. Introduction

Since December 2019, the outbreak of the novel coronavirus pneumonia firstly occurred in Wuhan, a central and packed city of China ^[1,2]. The World Health Organization(WHO) has named the virus as COVID-19 On January 12, 2020. Recently, COVID-19 has spread to the vast majority of countries, as United States, France, Iran, Italy and Spain etc. The outbreak of COVID-19 has been become a globally public health concern in medical community as the virus is spreading around the world. Initially, the British government adopted a herd immunity strategy. As of March 27, cases of the COVID-19 coronavirus have been confirmed more than 11,000 mostly In the UK. The symptoms of COVID-19 most like SARS(Severe acute respiratory syndrome) and MERS(Middle East respiratory syndrome), include cough, fever, weakness and difficulty breath^[3]. The period for such symptoms from mild to severe respiratory infections lasts 2–14 days. The transmission routes contain direct transmission, such as close touching and indirect transmission consist of the air by coughing and sneezing, even if contacting some contaminated things by virus particles. There are many mathematica models to discuss the dynamics of COVID-19 infection ^[4,5,6,7,8].

Additionally, coronaviruses can be extremely contagious and spread easily from person to person^[9]. So a series of stringent control measures are necessary. For some diseases, such as influenza and tuberculosis, people often introduce the latent compartment (denoted by $E$ ), leading to an SEIR model. The latent compartment of COVID-19 is highly contagious^[10,11]. Such type of models have been widely discussed in recent decades ^[12,13,14].

Media coverage is a key factor in the transmission process of infectious disease. People know more about the COVID-19 and enhance their self-protecting awareness by the media reporting about the COVID-19. People will change their behaviours and take correct precautions such as frequent hand-washing, wearing masks, reducing the party, keeping social distances, and even quarantining themselves at home to avoid contacting with others. Zhou et al.^[15] proposed a deterministic dynamical model to examine the interaction of the disease progression and the media reports and to investigate the effectiveness of media reporting on mitigating the spread of COVID-19. The result suggested that media coverage can be considered as an effective way to mitigate the disease spreading during the initial stage of an outbreak.

Quarantine is effective for the control of infectious disease. Chinese government advises all the Chinese citizens to isolate themselves at home, and people exposed to the virus have the medical observation for 14 days. In order to get closer to the reality, many scholars have introduced quarantine compartment into epidemic model. Amador and Gomez-Corral^[16] studied extreme values in an SIQS model with two different states for quarantine, termed quarantined susceptible and quarantined infective, and limited carrying capacity for the quarantine compartment. Gao and Zhuang proposed a new VEIQS worm propagation model with saturated incidence and strategies of both vaccination and quarantine^[17].

Motivated by the above, we consider a new COVID-19 epidemic model with media coverage and quarantine. The model assumes that the latent stage has certain infectivity. And we also introduce the quarantine compartment into the epidemic model, and the susceptible have consciousness to checking the spread of infectious diseases in the media coverage.

The organization of this paper is as follows. In the next section, the epidemic model with media coverage and quarantine is formulated. In section 3, the basic reproduction number and the existence of equilibria are investigated. In Section 4, the global stability of the disease free and endemic equilibria are proved. In Section 5, we use the MCMC algorithm to estimate the unknown parameters and initial values of the model. The basic reproduction number $R_{0}$ of the model and its confidence interval are solved by numerical methods. At the same time, we obtain the sensitivity of the unknown parameters of the model. In the last section, we give some discussions.

2. The model formulation

2.1. System description

In this section, we introduce a COVID-19 epidemic model with media coverage and quarantine. The total population is partitioned into six compartments: the unconscious susceptible compartment ( $S_{1}$ ), the conscious susceptible compartment ( $S_{2}$ ), the latent compartment ( $E$ ), the infectious compartment ( $I$ ), the quarantine compartment ( $Q$ ) and the recovered compartment ( $R$ ). The total number of population at time $t$ is given by

$N(t) = S_{1}(t)+S_{2}(t)+E(t)+I(t)+Q(t)+R(t).$

The parameters are described in Table 1. The population flow among those compartments is shown in the following diagram (Figure 1).

Table 1. Parameters of the model.

Parameter	Description
$\Lambda$	The birth rate of the population
$\beta_{E}$	Transmission coefficient of the latent compartment
$\beta_{I}$	Transmission coefficient of the infectious compartment
$\sigma$	The fraction of $S_{2}$ being infected and entering $E$
$p$	The migration rate to $S_{2}$ from $S_{1}$ , reflecting the impact of media coverage
$r$	The rate coefficient of transfer from the latent compartment
$q$	The fraction of the latent compartment $E$ jump into the quarantine compartment $Q$
$1-q$	The fraction of the latent compartment $E$ jump into the infectious compartment $I$
$\varepsilon$	The transition rate to $I$ for $Q$
$\xi$	The recovering rate of the quarantine compartment
$\mu$	Naturally death rate
$d$	The disease-related death rate

| Show Table

DownLoad: CSV

Figure 1. The transfer diagram for the model (2.1).

DownLoad: Full-Size Img PowerPoint

The transfer diagram leads to the following system of ordinary differential equations:

$\begin{equation} \begin{cases} {S_{1}}' = \Lambda-\beta_{E} S_{1}E-\beta_{I} S_{1}I-(p+\mu)S_{1}, \\ {S_{2}}' = pS_{1}-\beta_{E}\sigma S_{2}E-\beta_{I}\sigma S_{2}I-\mu S_{2}, \\ {E}' = \beta_{E}E( S_{1}+\sigma S_{2})+\beta_{I}I( S_{1}+\sigma S_{2})-(r+\mu)E, \\ {I}' = (1-q)rE-(\mu+d+\varepsilon)I, \\ {Q}' = qrE+\varepsilon I-(\mu+d+\xi)Q,\\ {R}' = \xi Q-\mu R. \end{cases} \end{equation}$

(2.1)

Since the sixth equation in system (2.1) is independent of other equations, system (2.1) may be reduced to the following system:

(2.2)

2.2. Basic properties

2.2.1. Positivity of solutions

It is important to show positivity for the system (2.1) as they represent populations. We thus state the following lemma.

Lemma 1. If the initial values $S_{1}(0) > 0$ , $S_{2}(0) > 0$ , $E(0) > 0$ , $I(0) > 0$ , $Q(0) > 0$ and $R(0) > 0$ , the solutions $S_{1}(t)$ , $S_{2}(t)$ , $E(t)$ , $I(t)$ , $Q(t)$ and $R(t)$ of system (2.1) are positive for all $t > 0$ .

Proof. Let $W(t) = \min\{S_{1}(t), S_{2}(t), E(t), I(t), Q(t), R(t)\}$ , for all $t > 0$ .

It is clear that $W(0) > 0$ . Assuming that there exists a $t_{1} > 0$ such that $W(t_{1}) = 0$ and $W(t) > 0$ , for all $t \in [0, t_{1})$ .

If $W(t_{1}) = S_{1}(t_{1})$ , then $S_{2}(t)\geq 0, \; E(t)\geq 0, \; I(t)\geq 0, \; Q(t)\geq 0, \; R(t)\geq 0$ for all $t \in [0, t_{1}]$ . From the first equation of model (2.1), we can obtain

$\begin{equation*} {S_{1}}' \geq-\beta_{E} S_{1}E-\beta_{I} S_{1}I-(p+\mu)S_{1}, \quad \quad t \in [0, t_{1}] \end{equation*}$

Thus, we have

$\begin{equation*} 0 = S_{1}(t_{1})\geq S_{1}(0)e^{-\int_0^{t_{1}}{[\beta_{E}E+\beta_{I}I+(p+\mu)]}dt} > 0, \end{equation*}$

which leads to a contradiction. Thus, $S_{1}(t) > 0$ for all $t\geq 0$ .

Similarly, we can also prove that $S_{2}(t) > 0$ , $E(t) > 0$ , $I(t) > 0$ , $Q(t) > 0$ and $R(t) > 0$ for all $t\geq 0$ .

2.2.2. Invariant region

Lemma 2. The feasible region $\Omega$ defined by

$\Omega = \{(S_{1}(t),\;S_{2}(t),\;E(t),\;I(t),\;Q(t),\;R(t))\in R_{+}^6:N(t)\leq \frac \Lambda \mu \}$

with initial conditions $S_{1}(0)\geq 0, \; S_{2}(0)\geq 0, \; E(0)\geq 0, \; I(0)\geq 0, \; Q(0)\geq 0, \; R(0)\geq 0$ is positively invariant for system (2.1).

Proof. Adding the equations of system (2.1) we obtain

$\begin{align*} \frac{dN}{dt}& = \Lambda -\mu N-d(I+Q) \\ &\leq\Lambda -\mu N. \end{align*}$

It follows that

$0\leq N(t)\leq \frac \Lambda \mu +N(0)e^{-\mu t},$

where $N(0)$ represents the initial values of the total population. Thus $\lim\limits_{t\rightarrow +\infty }\sup \; N\left(t\right) \leq \frac \Lambda \mu$ . It implies that the region $\Omega = \{(S_{1}(t), \; S_{2}(t), \; E(t), \; I(t), \; Q(t), \; R(t))\in R_{+}^6:N(t) \leq \frac \Lambda \mu \}$ is a positively invariant set for system (2.1). So we consider dynamics of system (2.1) and (2.2) on the set $\Omega$ in this paper.

3. The basic reproduction number and existence of equilibria

The model has a disease free equilibrium $(S_{1}^{0}, S_{2}^{0}, 0, 0, 0)$ , where

$S_{1}^{0} = \frac{\Lambda}{p +\mu },\qquad\qquad S_{2}^{0} = \frac{p\Lambda}{\mu(p +\mu )}. \label{3.1}$

In the following, the basic reproduction number of system (2.2) will be obtained by the next generation matrix method formulated in ^[18].

Let $x = (E, \; I, \; Q, \; S_{1}, \; S_{2})^T$ , then system (2.2) can be written as

$\frac{dx}{dt} = \mathcal{F}(x)-\mathcal{V}(x), \label{3.2}$

where

$\begin{equation} \mathcal{F}(x) = \left( \begin{array}{c} \beta_{E}E( S_{1}+\sigma S_{2})+\beta_{I}I( S_{1}+\sigma S_{2}) \\ 0 \\ 0 \\ 0 \\ 0 \end{array} \right) ,\qquad \mathcal{V}(x) = \left( \begin{array}{c} (r+\mu)E \\ (\mu+d+\varepsilon)I-(1-q)rE \\ (\mu+d+\xi)Q-qrE-\varepsilon I\\ \beta_{E} S_{1}E+\beta_{I} S_{1}I+(p+\mu)S_{1}-\Lambda\\ \beta_{E}\sigma S_{2}E+\beta_{I}\sigma S_{2}I+\mu S_{2}-pS_{1}\\ \end{array} \right) . \end{equation}$

(3.1)

The Jacobian matrices of $\mathcal{F}(x)$ and $\mathcal{V}(x)$ at the disease free equilibrium $P^{0}$ are, respectively,

$\begin{equation} D\mathcal{F}(P^{0}) = \left( \begin{array}{cc} F_{3\times 3} & 0 \\ 0 & 0 \end{array} \right) ,\qquad D\mathcal{V}(P^{0}) = \left( \begin{array}{ccc} V_{3\times3 } & 0 & 0 \\ \beta_{E}S_{1}^{0}\quad \beta_{I}S_{1}^{0}\quad 0 & p+\mu & 0 \\ \beta_{E}\sigma S_{2}^{0}\quad \beta_{I}\sigma S_{2}^{0}\quad 0 & -p & \mu \end{array} \right) , \end{equation}$

(3.2)

where

$\begin{equation} F = \left( \begin{array}{ccc} \beta_{E}(S_{1}^{0}+\sigma S_{2}^{0}) & \beta_{I}(S_{1}^{0}+\sigma S_{2}^{0}) & 0 \\ 0 & 0 & 0 \\ 0 & 0 & 0 \end{array} \right) ,\nonumber \qquad V = \left( \begin{array}{cccc} r+\mu & 0 & 0 \\ -(1-q)r & \mu+d+\varepsilon & 0 \\ -qr & -\varepsilon & \mu+d+\xi \end{array} \right) . \end{equation}$

The model reproduction number, denoted by $R_{0}$ is thus given by

$\begin{eqnarray} R_0& = &\rho (FV^{-1}) = \frac{(S_{1}^{0}+\sigma S_{2}^{0})[\beta_{E}(\mu+d+\varepsilon) +\beta_{I}(1-q)r]} {(r+\mu)(\mu+d+\varepsilon)} \\ & = &\frac{(S_{1}^{0}+\sigma S_{2}^{0})(\beta_{E}A+\beta_{I}B)}{(r+\mu)A}. \end{eqnarray}$

(3.3)

where

$\begin{equation} A = \mu+d+\varepsilon,\qquad\qquad\qquad B = (1-q)r. \end{equation}$

(3.4)

The endemic equilibrium $P^{*}(S_{1}^{*}, S_{2}^{*}, E^{*}, I^{*}, Q^{*})$ of system (2.2) is determined by equations

$\begin{equation} \begin{cases} \Lambda-\beta_{E} S_{1}E-\beta_{I} S_{1}I-(p+\mu)S_{1} = 0, \\ pS_{1}-\beta_{E}\sigma S_{2}E-\beta_{I}\sigma S_{2}I-\mu S_{2} = 0, \\ \beta_{E}E( S_{1}+\sigma S_{2})+\beta_{I}I( S_{1}+\sigma S_{2})-(r+\mu)E = 0, \\ (1-q)rE-(\mu+d+\varepsilon)I = 0, \\ qrE+\varepsilon I-(\mu+d+\xi)Q = 0. \end{cases} \end{equation}$

(3.5)

The first two equations in (3.5) lead to

$\begin{equation} S_{1} = \frac{\Lambda}{\beta_{E}E+\beta_{I}I+(p+\mu) },\qquad\qquad S_{2} = \frac{p\Lambda}{[\beta_{E}E+\beta_{I}I+(p+\mu)](\beta_{E}\sigma E+\beta_{I}\sigma I+\mu) }. \end{equation}$

(3.6)

From the fourth equation in (3.5), we have

$\begin{eqnarray} E& = &\frac{\mu+d+\varepsilon} {(1-q)r}I \\ & = &\frac {A}{B}I. \end{eqnarray}$

(3.7)

Substituting (3.7) into the last equation in (3.5) gives

$\begin{eqnarray} Q& = &\frac{q(\mu+d+\varepsilon)+(1-q)\varepsilon}{(1-q)(\mu+d+\xi)}I \\ & = &\frac{Aqr+B\varepsilon }{(\mu+d+\xi)B}I. \end{eqnarray}$

(3.8)

For $I\neq0$ , substituting (3.7) into the third equation in (3.5) gives

$\begin{equation} S_{1}+\sigma S_{2} = \frac {(r+\mu)A}{\beta_{E}A+\beta_{I}B} \end{equation}$

(3.9)

From (3.6) and (3.7), we have

$\begin{eqnarray} S_{1}+\sigma S_{2}& = &\frac{\Lambda}{\beta_{E}E+\beta_{I}I+(p+\mu) }+\frac{\sigma p\Lambda}{[\beta_{E}E+\beta_{I}I+(p+\mu)](\beta_{E}\sigma E+\beta_{I}\sigma I+\mu) } \\ & = &\frac{\Lambda}{\beta_{E}E+\beta_{I}I+(p+\mu) }\cdot[1+\frac{\sigma p}{\sigma(\beta_{E} E+\beta_{I}I)+\mu }] \\ & = &\frac{\Lambda}{\beta_{E}E+\beta_{I}I+(p+\mu) }\cdot\frac{\sigma(\beta_{E} E+\beta_{I}I)+\mu+p\sigma}{\sigma(\beta_{E} E+\beta_{I}I)+\mu } \\ & = &\frac{\Lambda}{\frac{\beta_{E}A+\beta_{I}B}{B}I+(p+\mu) }\cdot\frac{\sigma\frac{\beta_{E}A+\beta_{I}B}{B}I+\mu+p\sigma}{\sigma\frac{\beta_{E}A+\beta_{I}B}{B}I+\mu } \\ & = &\frac{B\Lambda}{(\beta_{E}A+\beta_{I}B)I+(p+\mu)B }\cdot\frac{\sigma(\beta_{E}A+\beta_{I}B)I+(\mu+p\sigma)B}{\sigma(\beta_{E}A+\beta_{I}B)I+\mu B }. \end{eqnarray}$

(3.10)

Substituting (3.9) into (3.10) yields

$\begin{eqnarray} H(I)&: = &\frac{B[\sigma(\beta_{E}A+\beta_{I}B)I+(\mu+p\sigma)B]}{[(\beta_{E}A+\beta_{I}B)I+(p+\mu)B][\sigma(\beta_{E}A+\beta_{I}B)I+\mu B] } -\frac {(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = &0. \end{eqnarray}$

(3.11)

Direct calculation shows

$H^{^{\prime }}(I) = \frac{H_{1}(I)}{\{[(\beta_{E}A+\beta_{I}B)I+(p+\mu)B][\sigma(\beta_{E}A+\beta_{I}B)I+\mu B]\}^2},$

Denote $C = \beta_{E}A+\beta_{I}B$ ,

$\begin{align*} H_{1}(I)& = B\sigma(\beta_{E}A+\beta_{I}B)[(\beta_{E}A+\beta_{I}B)I+(p+\mu)B][\sigma(\beta_{E}A+\beta_{I}B)I+\mu B]-B[\sigma(\beta_{E}A+\beta_{I}B)I\\ &+(\mu+p\sigma)B](\beta_{E}A+\beta_{I}B)\{[\sigma(\beta_{E}A+\beta_{I}B)I+\mu B]+\sigma[(\beta_{E}A+\beta_{I}B)I+(p+\mu) B]\}\\ & = \sigma BC[CI+(p+\mu)B][\sigma CI+\mu B]-BC[\sigma CI+(\mu+p\sigma) B]\{\sigma CI+\mu B+\sigma[CI+(p+\mu)B]\}\\ & = BC\{\sigma[CI+(p+\mu)B][\sigma CI+\mu B]-[\sigma CI+(\mu+p\sigma) B][\sigma CI+\mu B+\sigma[CI+(p+\mu)B]]\}\\ & = BC\{(\sigma\mu B-\mu B)(\sigma CI+\mu B)-[\sigma CI+(\mu+p\sigma) B]\sigma [CI+(p+\mu)B]\}\\ & = -BC\{\mu B(\sigma CI+\mu B)+\sigma[\sigma C^2I^2+\sigma pBCI+C(\mu+p\sigma)BI+[(\mu+p\sigma)p+p\sigma\mu]B^2]\}\\ & = -BC\{(\sigma C)^2I^2+2\sigma BC(\mu+\sigma p)I+B^2[\mu^2+\mu p\sigma+p(p+\mu)\sigma^2]\} < 0. \end{align*}$

then

$H^{^{\prime }}(I) < 0.$

then function $H(I)$ is decreasing for $I > 0$ . Since $[(\beta_{E}A+\beta_{I}B)I+(p+\mu)B][\sigma(\beta_{E}A+\beta_{I}B)I+\mu B] > (\beta_{E}A+\beta_{I}B)I[\sigma(\beta_{E}A+\beta_{I}B)I+(\mu+p\sigma)B]$ , then

$H(I) < \frac B{(\beta_{E}A+\beta_{I}B)I}-\frac {(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda}.$

Thus,

$\begin{align*} H(0) & = \frac{\mu+p\sigma}{\mu(p+\mu)}-\frac {(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = \frac{(S_{1}^{0}+\sigma S_{2}^{0})}\Lambda-\frac {(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = \frac{(\beta_{E}A+\beta_{I}B)(S_{1}^{0}+\sigma S_{2}^{0})-(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = \frac{(r+\mu)AR_0-(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = \frac{(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda}(R_{0}-1), \end{align*}$

and

$\begin{align*} H(\frac{\Lambda}\mu) & < \frac {\mu B}{(\beta_{E}A+\beta_{I}B)\Lambda}-\frac {(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = \frac {\mu B-(r+\mu)A}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = \frac {\mu(1-q)r-(r+\mu)(\mu+d+\varepsilon)}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & = -\frac {(r+\mu)(d+\varepsilon)+ (qr+\mu)\mu}{(\beta_{E}A+\beta_{I}B)\Lambda} \\ & < 0. \end{align*}$

Therefore, by the monotonicity of function $H(I)$ , for (3.11) there exists a unique positive root in the interval $(0, \frac{\Lambda}\mu)$ when $R_{0} > 1$ ; there is no positive root in the interval $(0, \frac{\Lambda}\mu)$ when $R_{0}\leq1$ . We summarize this result in Theorem 3.1.

Theorem 3.1. For system (2.2), there is always the disease free equilibrium $P^{0}(S_{1}^{0}, S_{2}^{0}, 0, 0, 0)$ . When $R_{0} > 1$ , besides the disease free equilibrium $P^{0}$ , system (2.2) also has a unique endemic equilibrium $P^{*}(S_{1}^{*}, S_{2}^{*}, E^{*}, I^{*}, Q^{*})$ , where

$\begin{align*} S_{1}^{*}& = \frac{B\Lambda }{(\beta_{E}A+\beta_{I}B)I^{*}+(p+\mu)B}, \\ S_{2}^{*}& = \frac{p \Lambda B^2}{[(\beta_{E}A+\beta_{I}B)I^{*}+(p+\mu)B][(\beta_{E}A+\beta_{I}B)\sigma I^{*}+\mu B]}, \\ E^{*}& = \frac A BI^{*},\\ Q^{*}& = \frac{Aqr+B\varepsilon }{(\mu+d+\xi)B}I^{*}. \end{align*}$

and $I^{*}$ is the unique positive root of equation $H(I) = 0$ .

4. Global stability of equilibria

Theorem 4.1. For system (2.2), the disease free equilibrium $P^{0}$ is globally stable if $R_{0}\leq1$ ; the endemic equilibrium $P^{*}$ is globally stable if $R_{0} > 1$ .

4.1. Global stability of the disease free equilibrium

For the disease free equilibrium $P^{0}(S_{1}^{0}, S_{2}^{0}, 0, 0, 0)$ , $S_{1}^{0}$ and $S_{2}^{0}$ satisfies equations

$\begin{equation} \begin{cases} \Lambda-\beta_{E} S_{1}E-\beta_{I} S_{1}I-(p+\mu)S_{1} = 0, \\ pS_{1}-\beta_{E}\sigma S_{2}E-\beta_{I}\sigma S_{2}I-\mu S_{2} = 0, \end{cases} \end{equation}$

(4.1)

then (2.2) can be rewritten as follows:

$\begin{equation} \begin{cases} {S_{1}}' = S_{1}[\Lambda(\frac 1{S_{1}}-\frac 1{S_{1}^{0}})-\beta_{E}E-\beta_{I}I], \\ {S_{2}}' = S_{2}[p(\frac {S_{1}}{S_{2}}-\frac {S_{1}^{0}}{S_{2}^{0}})-\beta_{E}\sigma E-\beta_{I}\sigma I], \\ {E}' = (\beta_{E}E+\beta_{I}I)[(S_{1}^{0}+\sigma S_{2}^{0})+( S_{1}-S_{1}^{0})+\sigma (S_{2}-S_{2}^{0})]-(r+\mu)E, \\ {I}' = (1-q)rE-(\mu+d+\varepsilon)I, \\ {Q}' = qrE+\varepsilon I-(\mu+d+\xi)Q \end{cases} \end{equation}$

(4.2)

Define the Lyapunov function

$\begin{equation} V_{1} = (S_{1}-S_{1}^{0}-S_{1}^{0}\ln \frac {S_{1}}{S_{1}^{0}})+(S_{2}-S_{2}^{0}-S_{2}^{0}\ln \frac {S_{2}}{S_{2}^{0}})+ E+ \frac {(r+\mu)-\beta_{E}(S_{1}^{0}+\sigma S_{2}^{0})}{(1-q)r}I. \end{equation}$

(4.3)

The derivative of $V_{1}$ is given by

$\begin{eqnarray} {V_{1}}'& = &(S_{1}-S_{1}^{0})[\Lambda(\frac 1{S_{1}}-\frac 1{S_{1}^{0}})-\beta_{E}E-\beta_{I}I] \\ &&+(S_{2}-S_{2}^{0})[p(\frac {S_{1}}{S_{2}}-\frac {S_{1}^{0}}{S_{2}^{0}})-\beta_{E}\sigma E-\beta_{I}\sigma I] \\ &&+(\beta_{E}E+\beta_{I}I)[(S_{1}^{0}+\sigma S_{2}^{0})+( S_{1}-S_{1}^{0})+\sigma (S_{2}-S_{2}^{0})]-(r+\mu)E \\ &&+\frac {(r+\mu)-\beta_{E}(S_{1}^{0}+\sigma S_{2}^{0})}{(1-q)r}[(1-q)r E-(\mu+d+\varepsilon)I] \\ & = &\beta_{I}(S_{1}^{0}+\sigma S_{2}^{0})I-\frac {[(r+\mu)-\beta_{E}(S_{1}^{0}+\sigma S_{2}^{0})](\mu+d+\varepsilon)}{(1-q)r}I+F(S,I) \\ & = &\frac{(r+\mu)(\mu+d+\varepsilon)}{(1-q)r}(R_{0}-1)I+F(S,I), \\ & = &\frac{(r+\mu)A}B(R_{0}-1)I+F(S,I), \\ \end{eqnarray}$

(4.4)

where

$\begin{align*} F(S,I) = \Lambda(S_{1}-S_{1}^{0})(\frac 1{S_{1}}-\frac 1{S_{1}^{0}})+p(S_{2}-S_{2}^{0})(\frac {S_{1}}{S_{2}}-\frac {S_{1}^{0}}{S_{2}^{0}}). \end{align*}$

Denote $x = \frac {S_{1}}{S_{1}^{0}}, \; y = \frac {S_{2}}{S_{2}^{0}}$ , then

$\begin{align} F(S,I)& = \Lambda (x-1)(\frac 1x-1)+pS_{1}^{0}(y-1)(\frac xy-1) = :\overline{F}(x,y). \end{align}$

(4.5)

Applying (4.1) to function $\overline{F}(x, y)$ yields

$\begin{eqnarray} \overline{F}(x,y)& = &\Lambda(2-x-\frac 1x)+pS_{1}^{0}(x-y-\frac x y+1) \\ & = &(2\Lambda+pS_{1}^{0})-(\Lambda-pS_{1}^{0})x-\Lambda\frac 1x-pS_{1}^{0}y-pS_{1}^{0}\frac x y \\ & = &3pS_{1}^{0}+2\mu S_{1}^{0}-\mu S_{1}^{0}x-(pS_{1}^{0}+\mu S_{1}^{0})\frac 1x-pS_{1}^{0}y-pS_{1}^{0}\frac x y \\ & = &pS_{1}^{0}(3-\frac 1x-y-\frac x y)+\mu S_{1}^{0}(2-x-\frac 1x). \end{eqnarray}$

(4.6)

We have $\overline{F}(x, y)\leq0$ for $x, y > 0$ and $\overline{F}(x, y) = 0$ if and only if $x = y = 1$ . Since $R_{0}\leq 1$ , then ${V_{1}}'\leq0$ . It follows from LaSalle invariance principle ^[19] that the disease free equilibrium $P^{0}$ is globally asymptotically stable when $R_{0}\leq1$ .

4.2. Global stability of the endemic equilibrium

For the endemic equilibrium $P^{*}(S_{1}^{*}, S_{2}^{*}, E^{*}, I^{*}, Q^{*})$ , $S_{1}^{*}, S_{2}^{*}, E^{*}, I^{*}$ , and $Q^{*}$ satisfies equations

(4.7)

By applying (4.7) and denoting

$\frac {S_{1}}{S_{1}^{*}} = x,\quad \quad \frac {S_{2}}{S_{2}^{*}} = y, \quad \quad \frac E{E^{*}} = z,\quad \quad \frac I{I^{*}} = u,\quad \quad \frac Q{Q^{*}} = v$

we have

$\begin{equation} \begin{cases} {x}' = x[\frac {\Lambda}{S_{1}^{*}}(\frac 1{x}-1)-\beta_{E}E^{*}(z-1)-\beta_{I}I^{*}(u-1)], \\ {y}' = y[\frac {pS_{1}^{*}}{S_{2}^{*}}(\frac xy-1)-\beta_{E}\sigma E^{*}(z-1)-\beta_{I}\sigma I^{*}(u-1)], \\ {z}' = z\{\beta_{E}[S_{1}^{*}(x-1)+\sigma S_{2}^{*}(y-1)]+\frac {\beta_{I}I^{*}}{E^{*}}[S_{1}^{*}(\frac {xu}{z}-1)+\sigma S_{2}^{*}(\frac {yu}{z}-1)]\}, \\ {u}' = u\frac {(1-q)rE^{*}}{I^{*}}(\frac zu-1), \\ {v}' = v[\frac {qrE^{*}}{Q^{*}}(\frac zv-1)+\frac {\varepsilon I^{*}}{Q^{*}}(\frac uv-1)]. \end{cases} \end{equation}$

(4.8)

Define the Lyapunov function

$\begin{eqnarray} V_{2}& = &S_{1}^{*}(x-1-\ln x)+S_{2}^{*}(y-1-\ln y)+E^{*}(z-1-\ln z)+\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B} I^{*}(u-1-\ln u). \end{eqnarray}$

(4.9)

The derivative of $V_{2}$ is given by

$\begin{eqnarray} {V_{2}}'& = &S_{1}^{*}\frac {x-1}{x}{x}'+S_{2}^{*}\frac {y-1}{y}{y}' +E^{*}\frac {z-1}{z}{z}'+\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B} I^{*}\frac {u-1}{u}{u}' \\ & = &(x-1)[\Lambda(\frac 1{x}-1)-\beta_{E}S_{1}^{*}E^{*}(z-1)-\beta_{I}S_{1}^{*}I^{*}(u-1)] \\ &&+(y-1)[pS_{1}^{*}(\frac xy-1)-\beta_{E}\sigma S_{2}^{*} E^{*}(z-1)-\beta_{I}\sigma S_{2}^{*} I^{*}(u-1)] \\ &&+(z-1)\{\beta_{E}E^{*}[S_{1}^{*}(x-1)+\sigma S_{2}^{*}(y-1)]+\beta_{I}I^{*}[S_{1}^{*}(\frac {xu}{z}-1)+\sigma S_{2}^{*}(\frac {yu}{z}-1)]\} \\ &&+\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B}(u-1)(1-q)rE^{*}(\frac zu-1) \\ & = &\Lambda(x-1)(\frac 1{x}-1)-\beta_{I}S_{1}^{*}I^{*}(x-1)(u-1) \\ &&+pS_{1}^{*}(y-1)(\frac xy-1)-\beta_{I}\sigma S_{2}^{*} I^{*}(y-1)(u-1) \\ &&+\beta_{I}S_{1}^{*}I^{*}(z-1)(\frac {xu}{z}-1)+\beta_{I}\sigma S_{2}^{*}I^{*}(z-1)(\frac {yu}{z}-1) \\ &&+\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B}(1-q)rE^{*}(u-1)(\frac zu-1) \\ & = &\Lambda(2-x-\frac 1{x})-\beta_{I}S_{1}^{*}I^{*}(xu-x-u-1)+pS_{1}^{*}(x-y-\frac xy+1) \\ &&-\beta_{I}\sigma S_{2}^{*} I^{*}(yu-y-u+1)+\beta_{I}S_{1}^{*}I^{*}(xu-z-\frac {xu}{z}+1) +\beta_{I}\sigma S_{2}^{*}I^{*}(yu-z-\frac {yu}{z}+1) \\ &&+\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B}(1-q)rE^{*}(z-u-\frac zu+1) \\ & = &2\Lambda+pS_{1}^{*}+\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B}(1-q)rE^{*}-x(\Lambda-\beta_{I}S_{1}^{*}I^{*}-pS_{1}^{*})-\Lambda\frac 1{x}-y(pS_{1}^{*}-\beta_{I}\sigma S_{2}^{*} I^{*}) \\ &&-pS_{1}^{*}\frac xy-\beta_{I}S_{1}^{*}I^{*}\frac {xu}{z} -\beta_{I}\sigma S_{2}^{*}I^{*}\frac {yu}{z}-\frac {\beta_{I}(r+\mu)}{\beta_{E}A+\beta_{I}B}(1-q)rE^{*}\frac zu \\ & = &(\Lambda-\beta_{I}S_{1}^{*}I^{*}-pS_{1}^{*})(2-x-\frac 1{x})+(pS_{1}^{*}-\beta_{I}\sigma S_{2}^{*}I^{*})(3-\frac 1{x}-y-\frac xy) \\ &&+\beta_{I}S_{1}^{*}I^{*}(3-\frac 1{x}-\frac {xu}{z}-\frac zu) +\beta_{I}\sigma S_{2}^{*}I^{*}(4-\frac 1{x}-\frac xy-\frac {yu}{z}-\frac zu) \end{eqnarray}$

(4.10)

Since the arithmetical mean is greater than, or equal to the geometrical mean, then, $2-x-\frac 1x\leq0$ for $x > 0$ and $2-x-\frac 1x = 0$ if and only if $x = 1$ ; $3-\frac 1{x}-y-\frac xy\leq0$ for $x, y > 0$ and $3-\frac 1{x}-y-\frac xy = 0$ if and only if $x = y = 1$ ; $3-\frac 1x-\frac{xu}z-\frac zu\leq0$ for $x, z, u > 0$ and $3-\frac 1x-\frac{xu}z-\frac zu = 0$ if and only if $x = 1, z = u$ ; $4-\frac 1{x}-\frac xy-\frac {yu}{z}-\frac zu\leq0$ for $x, y, z, u > 0$ and $4-\frac 1{x}-\frac xy-\frac {yu}{z}-\frac zu = 0$ if and only if $x = y = 1, z = u$ . Therefore, ${V_{2}}'\leq0$ for $x, y, z, u > 0$ and ${V_{2}}' = 0$ if and only if $x = y = 1, z = u$ , the maximum invariant set of system (2.2) on the set $\{(x, y, z, u):{V_{2}}' = 0\}$ is the singleton $(1, 1, 1, 1)$ . Thus, for system (2.2), the endemic equilibrium $P^{*}$ is globally asymptotically stable if $R_{0} > 1$ by LaSalle Invariance Principle ^[19].

5. A case study

In this section, we estimate the unknown parameters of model (2.2) on the basis of the total confirmed new cases in the UK from February 1, 2020 to March 23, 2020 by using MCMC algorithm. By estimating the unknown parameters, we estimate the mean and confidence interval of the basic reproduction number $R_{0}$ .

5.1. Parameter estimation and model fitting

The total confirmed cases can be expressed as follows

$\begin{equation*} \frac{dC}{dt} = qrE+\varepsilon I, \end{equation*}$

where $C(t)$ indicates the total confirmed cases.

As for the total confirmed new cases, it can be expressed as following

$\begin{equation} NC = C(t)-C(t-1), \end{equation}$

(5.1)

where $NC$ represents the total confirmed new cases.

We use the MCMC method ^[20,21,22] for 20000 iterations with a burn-in of 5000 iterations to fit the Eq (5.1) and estimate the parameters and the initial conditions of variables (see Table 2). shows a good fitting between the model solution and real data, well suggesting the epidemic trend in the United Kingdom. According to the estimated parameter values and initial conditions as given in , we estimate the mean value of the reproduction number $R_{0} = 4.2816$ ( $95\% \mbox{CI}: (3.8882, 4.6750)$ ).

Table 2. The parameters values and initial values of the model (2.2).

Parameters	Mean value	Std	$95\%$ CI	Reference
$\Lambda$	$0$	$-$	$-$	Estimated
$\mu$	$0$	$-$	$-$	Estimated
$d$	$1/18$	$-$	$-$	^[23]
$\gamma$	$1/7$	$-$	$-$	^[24]
$\xi$	$1/18$	$-$	$-$	^[23]
$\beta_{E}$	$5.1561\times10^{-9}$	$5.1184\times10^{-10}$	[ $0.4153\times10^{-8}$ , $0.6159\times10^{-8}$ ]	MCMC
$\beta_{I}$	$2.3204\times10^{-8}$	$3.1451\times10^{-9}$	[ $0.1704\times10^{-7}$ , $0.2937\times10^{-7}$ ]	MCMC
$p$	$0.5961$	$0.0377$	[ $0.5223$ , $0.6700$ ]	MCMC
$q$	$0.2250$	$0.0787$	[ $0.0707$ , $0.3793$ ]	MCMC
$\sigma$	$0.3754$	$0.0135$	[ $0.3490$ , $0.4018$ ]	MCMC
$\varepsilon$	$0.2642$	$0.0598$	[ $0.1470$ , $0.3814$ ]	MCMC
$S_1(0)$	$3.3928\times10^{7}$	$2.9130\times10^{6}$	[ $2.8219\times10^{7}$ , $3.9638\times10^{7}$ ]	Calculated
$S_2(0)$	$3.2645\times10^{7}$	$2.9130\times10^{6}$	[ $2.6936\times10^{7}$ , $3.8355\times10^{7}$ ]	MCMC
$E(0)$	$12.8488$	$3.2238$	[ $6.5302$ , $19.1674$ ]	MCMC
$I(0)$	$0.8070$	$0.7739$	[ $0$ , $2.3239$ ]	MCMC
$Q(0)$	$2$	$-$	$-$	^[25]
$R(0)$	$0$	$-$	$-$	Estimated
$N(0)$	$66573504$	$-$	$-$	^[26]

| Show Table

DownLoad: CSV

Figure 2. The fitting results of the total confirmed new cases from February 1, 2020 to March 23, 2020. The blue line is the simulated curve of model (2.2). The red dots represent the actual data. The light blue area is the

$95\%$ confidence interval (CI) for all 5000 simulations.

DownLoad: Full-Size Img PowerPoint

5.2. Prediction of epidemiological quantities

Applying the estimated parameter values, without the most restrictive measures in UK, we forecast that the peak size is $1.2902\times 10^{6}$ ( $95\% \mbox{CI}: (1.1429\times 10^{6}, 1.4374\times 10^{6})$ ), the peak time is June 2 ( $95\% \mbox{CI}: (\mbox{May}\; 23, \mbox{June} \; 13)$ ) (), and the final size is $4.9437\times 10^{7}$ ( $95\% \mbox{CI}: (4.7199\times 10^{7}, 5.1675\times 10^{7})$ ) in the UK (Figure 3b).

Figure 3. (a) Forecasting trends of total confirmed new cases. (b) Forecasting trends of total confirmed cases. The blue line is the simulated curve of model (2.2). The red dots represent the actual data. The light blue area is the

$95\%$ confidence interval (CI) for all 5000 simulations.

DownLoad: Full-Size Img PowerPoint

5.3. Sensitivity analysis

In this section, we do the sensitivity analysis for four vital model parameters $\sigma$ , $p$ , $q$ and $\varepsilon$ , which reflect the intensity of contact, media coverage and isolation, respectively.

and show that reducing the fraction $\sigma$ of the conscious susceptible $S_{2}$ contacting with the latent compartment ( $E$ ) and the infectious compartment ( $I$ ) delays the peak arrival time, decreases the peak size of confirmed cases and decreases the final size. Reducing the fraction $\sigma$ is in favor of controlling COVID-19 transmission.

Figure 4. (a) Effects of different Parameter

$\sigma$ on The numbers of total confirmed new cases. (b) Effects of different Parameter

$\sigma$ on The numbers of total confirmed cases.

DownLoad: Full-Size Img PowerPoint

Table 3. Epidemic quantities for the UK.

Parameter	Peak size	Peak time	Final size
$\sigma=0.3652$	$1.2056\times10^{6}$	May 23	$4.9766\times10^{7}$
$\sigma=0.32$	$9.4930\times10^{5}$	June 25	$4.5390\times10^{7}$
$\sigma=0.3$	$8.1063\times10^{5}$	July 13	$4.3121\times10^{7}$
$p=0.5961$	$1.3056\times10^{6}$	May 23	$4.9766\times10^{7}$
$p=1/20$	$1.3248\times10^{6}$	May 19	$4.9864\times10^{7}$
$p=1/40$	$1.5009\times10^{6}$	May 3	$5.0699\times10^{7}$
$q=0.2250$	$1.3056\times10^{6}$	May 23	$4.9766\times10^{7}$
$q=0.3375$	$1.1379\times10^{6}$	June 6	$4.8471\times10^{7}$
$q=0.4500$	$9.4266\times10^{5}$	June 27	$4.6141\times10^{7}$
$\varepsilon=0.2642$	$1.3056\times10^{6}$	May 23	$4.9766\times10^{7}$
$\varepsilon=0.3170$	$1.1766\times10^{6}$	June 2	$4.8598\times10^{7}$
$\varepsilon=0.3963$	$9.9640\times10^{5}$	June 18	$4.6145\times10^{7}$

| Show Table

DownLoad: CSV

and show that reducing migration rate $p$ to $S_{2}$ from $S_{1}$ , reflecting the impact of media coverage advances the peak arrival time, increase the peak size of confirmed cases and the final size.

Figure 5. (a) Effects of different Parameter

$p$ on The numbers of total confirmed new cases. (b) Effects of different Parameter

$p$ on The numbers of total confirmed cases.

DownLoad: Full-Size Img PowerPoint

Figures 6, and show that, with increase the fraction $q$ (Individuals in the latent compartment $E$ jump into the quarantine compartment $Q$ ) and the transition rate $\varepsilon$ (the infectious compartment $I$ jump into the quarantine compartment $Q$ ), the peak time delays, the the peak size and the final size decrease. This show that Increasing the intensity of detection and isolation may affect the spread of COVID-19.

Figure 6. (a) Effects of different Parameter

$q$ on The numbers of total confirmed new cases. (b) Effects of different Parameter

$q$ on The numbers of total confirmed cases.

DownLoad: Full-Size Img PowerPoint

Figure 7. (a) Effects of different Parameter

$\varepsilon$ on The numbers of total confirmed new cases. (b) Effects of different Parameter

$\varepsilon$ on The numbers of total confirmed cases.

DownLoad: Full-Size Img PowerPoint

Then the test set data is used to verify the short-term prediction effect of the model (Figure 8). we fit the model with the total confirmed new cases from February 1, 2020 to March 23, 2020, and verify the fitting results with the new cases from March 24, 2020 to April 12, 2020. The model has a good fit to the trajectory of the coronavirus prevalence for a short time in the UK.

Figure 8. The test set data is used to verify the short-term prediction effect of the model.

DownLoad: Full-Size Img PowerPoint

6. Discussions

We have formulated the COVID-19 epidemic model with media coverage and quarantine and investigated their dynamical behaviors. By means of the next generation matrix, we obtained their basic reproduction number, $R_{0}$ , which play a crucial role in controlling the spread of COVID-19. By constructing Lyapunov function, we proved the global stability of their equilibria: when the basic reproduction number is less than or equal to one, all solutions converge to the disease free equilibrium, that is, the disease dies out eventually; when the basic reproduction number exceeds one, the unique endemic equilibrium is globally stable, that is, the disease will persist in the population and the number of infected individuals tends to a positive constant. We use the MCMC algorithm to estimate the unknown parameters and initial values of the model (2.2) on the basis of the total confirmed new cases in the UK. The sensitivity of all parameters are evaluated.

Through the mean and confidence intervals of the parameters in , we obtain the basic reproduction number $R_{0} = 4.2816$ ( $95\% \mbox{CI}: (3.8882, 4.6750)$ ), which means that the novel coronavirus pneumonia is still pandemic in the crowd. The sensitivity of the parameters provides a possible intervention to reduce COVID-19 infection. People should wear masks, avoid contact or reduce their outings, take isolation measure to reduce the spread of virus during COVID-19 outbreaks.

Acknowledgments

We are grateful to the anonymous referees and the editors for their valuable comments and suggestions which improved the quality of the paper. This work is supported by the National Natural Science Foundation of China (11861044 and 11661050), and the HongLiu first-class disciplines Development Program of Lanzhou University of Technology.

Conflict of interest

The authors declare there is no conflict of interest.

References

[1]	Susila AD, Syukur M, Dharma, HPK, et al. (2012) Koleksi dan identifikasi: tanaman sayuran indigenous. Pusat Kajian Hortikultura Tropika LPPM IPB.
[2]	Bunawan H, Baharum S, Noor NM (2014) Cosmos Caudatus cunth: A traditional medicinal herb. Global J Pharmacol 8: 420–426.
[3]	Fabbri ADT, Crosby GA (2016) A review of the impact of preparation and cooking on the nutritional quality of vegetables and legumes. Inter J Gastro Food Sci 3: 2–11. https://doi.org/10.1016/j.ijgfs.2015.11.001 doi: 10.1016/j.ijgfs.2015.11.001
[4]	Putriani N, Meiliana PJ, Nugrahedi PY (2020) Effect of thermal processing on key phytochemical compounds in green leafy vegetables: A Review. Food Rev Inter 38: 783–811. https://doi.org/10.1080/87559129.2020.1745826 doi: 10.1080/87559129.2020.1745826
[5]	Armesto J, Gómez-Limia L, Carballo J, et al. (2018) Effects of different cooking methods on the antioxidant capacity and flavonoid, organic acid, and mineral contents of Galega Kale (Brassica oleracea var. acephala cv. Galega). Inter J Food Sci Nutr 70: 136–149. https://doi.org/10.1080/09637486.2018.1482530 doi: 10.1080/09637486.2018.1482530
[6]	Wieczorek M, Jeleń H (2019) Volatile compounds of selected raw and cooked brassica vegetables. Molecules, 24: 391. https://doi.org/10.3390/molecules24030391 doi: 10.3390/molecules24030391
[7]	Javadi N, Abas F, Hamid AA, et al. (2014) GC-MS-based metabolite profiling of Cosmos caudatus leaves possessing alpha-glucosidase inhibitory activity. J Food Sci 79: C1130–C1136. https://doi.org/10.1111/1750-3841.12491 doi: 10.1111/1750-3841.12491
[8]	Javadi N, Abas F, Mediani A, et al. (2015) Effect of storage time on metabolite profile and alpha-glucosidase inhibitory activity of Cosmos caudatus leaves - GCMS based metabolomics approach. J Food Drug Anal 23: 433–441. https://doi.org/10.1016/j.jfda.2015.01.005 doi: 10.1016/j.jfda.2015.01.005
[9]	Amalia L, Anggadiredja K, Sukrasno, et al. (2012) Antihypertensive potency of wild cosmos (Cosmos caudatus Kunth, Asteraceae) leaf extract. J Pharmacol Toxicol 7: 359–368. https://doi.org/10.3923/jpt.2012.359.368 doi: 10.3923/jpt.2012.359.368
[10]	Lee T K, Vairappan CS (2011) Antioxidant, antibacterial and cytotoxic activities of essential oils and ethanol extracts of selected South East Asian herbs. J Med Plant Res 5: 5284–5290.
[11]	Ardiansyah, Fadilah R, Handoko DD, et al. (2019) Efek pemanasan skala rumah tangga terhadap komponen bioaktif daun kenikir (Cosmos caudatus). Agritech 39: 207–214. https://doi.org/10.22146/agritech.43894 doi: 10.22146/agritech.43894
[12]	Punter PH (2018) Free choice profiling. In: Descriptive Analysis in Sensory Evaluation, John Wiley & Sons, Ltd., 493–511. https://doi.org/10.1002/9781118991657.ch13
[13]	Ardiansyah, Ohsaki Y, Shirakawa H, et al. (2008) Novel effects of a single administration of ferulic acid on the regulation of blood pressure and the hepatic lipid metabolic profile in stroke-prone spontaneously hypertensive rats. J Agric Food Chem 56: 2825–2830. https://doi.org/10.1021/jf072896y doi: 10.1021/jf072896y
[14]	Ardiansyah, Ariffa F, Astuti, RM, et al. (2021) Non-volatile compounds and blood pressure-lowering activity of Inpari 30 and Cempo Ireng fermented and non-fermented rice bran. AIMS Agric Food 6: 337–359. https://doi.org/10.3934/agrfood.2021021 doi: 10.3934/agrfood.2021021
[15]	Pareek S, Sagar NA, Sharma S, et al. (2017) Chlorophylls: chemistry and biological functions. In: Fruit and Vegetable Phytochemicals, John Wiley & Sons, Ltd., 269–284. https://doi.org/10.1002/9781119158042.ch14
[16]	Paciulli M, Palermo M, Chiavaro E, et al. (2017). Chlorophylls and colour changes in cooked vegetables. In: Fruit and Vegetable Phytochemicals, John Wiley & Sons, Ltd., 703–719. https://doi.org/10.1002/9781119158042.ch31
[17]	Gaur S, Ahmed J (2006) Degradation of chlorophyll during processing of green vegetables: A review. Stewart Postharvest Rev 2: 1–8. https://doi.org/10.2212/spr.2006.5.14 doi: 10.2212/spr.2006.5.14
[18]	Tripathi J, Gupta S, Gautam S (2022) Alpha-cadinol as a potential ACE-inhibitory volatile compound identified from Phaseolus vulgaris L. through in vitro and in silico analysis. J Biomol Struct Dyn 5: 1–15. https://doi.org/10.1080/07391102.2022.2057359 doi: 10.1080/07391102.2022.2057359
[19]	Latiff NA, Abdullah LC, Ong PY, et al. (2020) The influence of drying temperature on the quality, morphology and drying characteristics of Cosmos caudatus. IOP Conference Series: Mat Sci Engin 991: 012038. https://doi.org/10.1088/1757-899X/991/1/012038 doi: 10.1088/1757-899X/991/1/012038
[20]	Joshi RK (2013) Chemical composition of the essential oils of aerial parts and flowers of Chromolaena odorata (L. ). J Ess Oil-Bearing Plants 16: 71–75. https://doi.org/10.1080/0972060X.2013.793971 doi: 10.1080/0972060X.2013.793971
[21]	Huong LT, Chung NT, Chau DT, et al. (2022) Annonaceae essential oils: antimicrobial and compositions of the leaves of Uvaria hamiltonii Hook. f. & thoms. and Fissistigma kwangsiensis tsiang & PT Li. Rec Nat Prod 4: 387–392. https://doi.org/10.25135/rnp.281.2108-2161 doi: 10.25135/rnp.281.2108-2161
[22]	Silva RC, Costa JS, Figueiredo RO, et al. (2021) Monoterpenes and sesquiterpenes of essential oils from psidium species and their biological properties. Molecules 26: 965. https://doi.org/10.3390/molecules26040965 doi: 10.3390/molecules26040965
[23]	Kunishima M, Yamauchi Y, Mizutani M, et al. (2016) Identification of (z)-3: (e)-2-hexenal isomerases essential to production of the leaf aldehyde in plants. J Biol Chem 291: 14023–14033. https://doi.org/10.1074/jbc.M116.726687 doi: 10.1074/jbc.M116.726687
[24]	Scala A, Allmann S, Mirabella R, et al. (2013) Green leaf volatiles: a plant's multifunctional weapon against herbivores and pathogens. Inter J Mol Sci 14: 17781–17811. https://doi.org/10.3390/ijms140917781 doi: 10.3390/ijms140917781
[25]	Baenas N, Bravo S, Garcia-Alonso FJ, et al. (2021) Changes in volatile compounds, flavour-related enzymes and lycopene in a refrigerated tomato juice during processing and storage. Europ Food Res Technol 247: 975–984. https://doi.org/10.1007/s00217-020-03678-7 doi: 10.1007/s00217-020-03678-7
[26]	Koltun SJ, Maclntosh AJ, Goodrich-Schneider RM, et al. (2021) Effects of thermal processing on flavor and consumer perception using tomato juice produced from Florida grown fresh market cultivars. J Food Process Preserv 46: e16164. https://doi.org/10.1111/jfpp.16164 doi: 10.1111/jfpp.16164
[27]	Guo S, Na Jom K, Ge Y (2019) Influence of roasting condition on flavor profile of sunflower seeds: A flavoromics approach. Sci Rep 9: 11295. https://doi.org/10.1038/s41598-019-47811-3 doi: 10.1038/s41598-019-47811-3
[28]	Zellner BD, Amorim CL, Miranda LP, et al. (2009) Screening of the odour-activity and bioactivity of the essential oils of leaves and flowers of Hyptis Passerina Mart. from the Brazilian cerrado. J Braz Chem Soc 20: 322–332. https://doi.org/10.1590/S0103-50532009000200018 doi: 10.1590/S0103-50532009000200018
[29]	Zhang Q, Lin X, Gai Y, et al. (2018) Kinetic and mechanistic study on gas phase reactions of ozone with a series of cis -3-hexenyl esters. RSC Advanc 8: 4230–4238. https://doi.org/10.1039/C7RA13369C doi: 10.1039/C7RA13369C
[30]	Reineccius G (2005) Flavor Chemistry and Technology, CRC Press. https://doi.org/10.1201/9780203485347
[31]	Szafranek B, Chrapkowska K, Pawińska M, et al. (2005) Analysis of leaf surface sesquiterpenes in potato varieties. J Agric Food Chem 53: 2817–2822. https://doi.org/10.1021/jf040437g doi: 10.1021/jf040437g
[32]	Ho CL, Liao PC, Wang EI, et al. (2011) Composition and antimicrobial activity of the leaf and twig oils of Litsea acutivena from Taiwan. Nat Prod Comm 6: 1755–1758. https://doi.org/10.1177/1934578X1100601145 doi: 10.1177/1934578X1100601145
[33]	Jiang Z, Jacob JA, Loganathachetti DS, et al. (2017) β-elemene: mechanistic studies on cancer cell interaction and its chemosensitization effect. Front in Pharmacol 8: 1–7. https://doi.org/10.3389/fphar.2017.00105 doi: 10.3389/fphar.2017.00105
[34]	Lorjaroenphon Y, Chaiseri S, Jirapakkul W (2015) Vegetable flavors and sensory characteristics. In: Hui YH, Evranuz EÖ, Bingöl G, et al. (Eds. ), Handbook of Vegetable Preservation and Processing, CRC Press, 57–80.
[35]	Borowski J, Narwojsz J, Borowska EJ, et al. (2016) The effect of thermal processing on sensory properties, texture attributes, and pectic changes in broccoli. Czech J Food Sci 33: 254–260. https://doi.org/10.17221/207/2014-CJFS doi: 10.17221/207/2014-CJFS
[36]	Liu J, Bredie WLP, Sherman E, et al. (2018) Comparison of rapid descriptive sensory methodologies: free-choice profiling, flash profile and modified flash profile. Food Res Inter 106: 892–900. https://doi.org/10.1016/j.foodres.2018.01.062 doi: 10.1016/j.foodres.2018.01.062
[37]	Pino JA, Marbot R, Fuentes V (2003) Characterization of volatiles in bullock's heart (Annona reticulata L. ) fruit cultivars from Cuba. J Agric Food Chem 51: 3836–3839. https://doi.org/10.1021/jf020733y doi: 10.1021/jf020733y
[38]	Pino J, Fuentes V, Barrios O (2011) Volatile constituents of Cachucha peppers (Capsicum chinense Jacq. ) grown in Cuba. Food Chem 125: 860–864. https://doi.org/10.1016/j.foodchem.2010.08.073 doi: 10.1016/j.foodchem.2010.08.073
[39]	Goodner KL (2008) Practical retention index models of OV-101, DB-1, DB-5, and DB-Wax for flavor and fragrance compounds. LWT-Food Sci Technol 41: 951–958. https://doi.org/10.1016/j.lwt.2007.07.007 doi: 10.1016/j.lwt.2007.07.007
[40]	Lopes-Lutz D, Alviano DS, Alviano CS, et al. (2008) Screening of chemical composition, antimicrobial and antioxidant activities of Artemisia essential oils. Phytochemi 69: 1732–1738. https://doi.org/10.1016/j.phytochem.2008.02.014 doi: 10.1016/j.phytochem.2008.02.014
[41]	Ali NAA, Wurster M, Arnold N, et al. (2008) Chemical composition and biological activities of essential oils from the oleogum resins of three endemic soqotraen Boswellia species. Rec Nat Prod 2: 6–12.
[42]	Flamini G, Cioni PL, Morelli I, et al. (2003) Differences in the fragrances of pollen, leaves, and floral parts of garland (Chrysanthemum coronarium) and composition of the essential oils from flowerheads and leaves. J Agric Food Chem 51: 2267–2271. https://doi.org/10.1021/jf021050l doi: 10.1021/jf021050l
[43]	Lago JHG, Soares MG, Batista-Pereira LG, et al. (2006) Volatile oil from Guarea macrophylla ssp. tuberculata: seasonal variation and electroantennographic detection by Hypsipyla grandella. Phytochem 67: 589–594. https://doi.org/10.1016/j.phytochem.2005.12.018 doi: 10.1016/j.phytochem.2005.12.018
[44]	Moon SYY, Cliff MA, Li-Chan ECYY (2006) Odour-active components of simulated beef flavour analysed by solid phase microextraction and gas chromatography–mass spectrometry and olfactometry. Food Res Inter 39: 294–308. https://doi.org/10.1016/j.foodres.2005.08.002 doi: 10.1016/j.foodres.2005.08.002

This article has been cited by:

1.	Zihan Yuan, Qingtang Su, Decheng Liu, Xueting Zhang, Tao Yao, Fast and robust image watermarking method in the spatial domain, 2020, 14, 1751-9659, 3829, 10.1049/iet-ipr.2019.1740
2.	Weitong Chen, Changqing Zhu, Na Ren, Tapio Seppanen, Anja Keskinarkaus, Screen-Cam Robust and Blind Watermarking for Tile Satellite Images, 2020, 8, 2169-3536, 125274, 10.1109/ACCESS.2020.3007689
3.	Zihan Yuan, Qingtang Su, Decheng Liu, Xueting Zhang, A blind image watermarking scheme combining spatial domain and frequency domain, 2020, 0178-2789, 10.1007/s00371-020-01945-y
4.	Xueting Zhang, Qingtang Su, Zihan Yuan, Decheng Liu, An efficient blind color image watermarking algorithm in spatial domain combining discrete Fourier transform, 2020, 219, 00304026, 165272, 10.1016/j.ijleo.2020.165272
5.	Yifei Wang, Qichao Ying, Yunlong Sun, Zhenxing Qian, Xinpeng Zhang, 2022, A DTCWT-SVD Based Video Watermarking Resistant to Frame Rate Conversion, 978-1-6654-6248-8, 36, 10.1109/CoST57098.2022.00017
6.	Hazem Munawer Al-Otum, Colour Image Authentication and Recovery Using Wavelet Packets Watermarking, 2022, 41, 0278-081X, 3222, 10.1007/s00034-021-01927-y
7.	Azza Dandooh, Adel S. El‐Fishawy, Fathi E. Abd El‐Samie, Ezz El‐Din Hemdan, Secure audio signal transmission based on color image watermarking, 2022, 5, 2475-6725, 10.1002/spy2.185
8.	Hazem Munawer Al-Otum, Dual image watermarking using a multi-level thresholding and selective zone-quantization for copyright protection, authentication and recovery applications, 2022, 81, 1380-7501, 25787, 10.1007/s11042-022-11920-5
9.	SiMing Xing, Tong Yi Li, Jing Liang, A Zero-Watermark Hybrid Algorithm for Remote Sensing Images Based on DCT and DFT, 2021, 1952, 1742-6588, 022049, 10.1088/1742-6596/1952/2/022049
10.	Manuel Cedillo-Hernandez, Antonio Cedillo-Hernandez, Francisco J. Garcia-Ugalde, Improving DFT-Based Image Watermarking Using Particle Swarm Optimization Algorithm, 2021, 9, 2227-7390, 1795, 10.3390/math9151795
11.	Hazem Munawer Al-Otum, Arwa Abdelnaser Ali Ellubani, Secure and effective color image tampering detection and self restoration using a dual watermarking approach✩, 2022, 262, 00304026, 169280, 10.1016/j.ijleo.2022.169280
12.	Yangming Zhou, Qichao Ying, Yifei Wang, Xiangyu Zhang, Zhenxing Qian, Xinpeng Zhang, 2022, Robust Watermarking for Video Forgery Detection with Improved Imperceptibility and Robustness, 978-1-6654-7189-3, 1, 10.1109/MMSP55362.2022.9949466
13.	M Amrutha., A. Kannammal, 2022, Double Security to Colour Images with DCT based Watermarking and Chaos based Encryption, 978-1-6654-5653-1, 130, 10.1109/ICIIET55458.2022.9967591
14.	Qichao Ying, Xiaoxiao Hu, Xiangyu Zhang, Zhenxing Qian, Sheng Li, Xinpeng Zhang, 2022, RWN: Robust Watermarking Network for Image Cropping Localization, 978-1-6654-9620-9, 301, 10.1109/ICIP46576.2022.9897870
15.	Mei-Juan Zuo, Shan Cheng, Li-Hua Gong, Secure and robust watermarking scheme based on the hybrid optical bi-stable model in the multi-transform domain, 2022, 81, 1380-7501, 17033, 10.1007/s11042-022-12035-7
16.	Xueying Mao, Xiaoxiao Hu, Wanli Peng, Zhenliang Gan, Zhenxing Qian, Xinpeng Zhang, Sheng Li, 2024, From Covert Hiding To Visual Editing: Robust Generative Video Steganography, 9798400706868, 2757, 10.1145/3664647.3681149
17.	Xiaoxiao Hu, Qichao Ying, Zhenxing Qian, Sheng Li, Xinpeng Zhang, 2023, DRAW: Defending Camera-shooted RAW against Image Manipulation, 979-8-3503-0718-4, 22377, 10.1109/ICCV51070.2023.02050
18.	Zhihua Gan, Xiaolong Zheng, Yalin Song, Xiuli Chai, Screen-shooting watermarking algorithm based on Harris-SIFT feature regions, 2024, 18, 1863-1703, 4647, 10.1007/s11760-024-03102-7
19.	Shireen Alshaikhli, Alaa Kadhim Farhan, 2022, A Survey on Fruit Fly Optimization Algorithm (FOA) in Robust Secure Color Image Watermarking, 979-8-3503-3492-0, 36, 10.1109/CSCTIT56299.2022.10145715

Reader Comments

Your name:*

Email:*
© 2023 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

AIMS Agriculture and Food

1.9 3.9

Metrics

Article views(2600) PDF downloads(172) Cited by(0)

Preview PDF

Download XML

Export Citation

Article outline

Show full outline

AIMS Agriculture and Food

Effects of household-scale cooking on volatile compounds, sensory profile, and hypotensive effect of Kenikir (Cosmos caudatus)

Related Papers:

Abstract

1. Introduction

2. The model formulation

2.1. System description

2.2. Basic properties

2.2.1. Positivity of solutions

2.2.2. Invariant region

3. The basic reproduction number and existence of equilibria

4. Global stability of equilibria

4.1. Global stability of the disease free equilibrium

4.2. Global stability of the endemic equilibrium

5. A case study

5.1. Parameter estimation and model fitting

5.2. Prediction of epidemiological quantities

5.3. Sensitivity analysis

6. Discussions

Acknowledgments

Conflict of interest

References

This article has been cited by:

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Related pages

Tools

Export File

Citation

Format

Content

Catalog

Abstract

1. Introduction

2. The model formulation

2.1. System description

2.2. Basic properties

2.2.1. Positivity of solutions

2.2.2. Invariant region

3. The basic reproduction number and existence of equilibria

4. Global stability of equilibria

4.1. Global stability of the disease free equilibrium

4.2. Global stability of the endemic equilibrium

5. A case study

5.1. Parameter estimation and model fitting

5.2. Prediction of epidemiological quantities

5.3. Sensitivity analysis

6. Discussions

Acknowledgments

Conflict of interest

References